A forwardly directed fluid jet crossing catheter having a distally directed cylindrical flow fluid jet stream to cross a chronic total occlusion is set forth. The distal end of the device includes a formable catheter tip region having flexible internal components. Low and high pressure cavities are formed substantially by joined proximal and distal catheter tubes having an adhesive plug seal in common therebetween which partially defines one end of each of the low pressure and high pressure cavities. A guidewire tube and a high pressure tube are aligned along and within the low pressure and high pressure cavities and through the adhesive plug seal. The high pressure tube openly terminates in the high pressure cavity, whereby pressurized fluid transfers from the high pressure cavity in the guidewire tube entry hole to subsequently pass along the guidewire lumen and co-located guidewire to exit as a cylindrical fluid jet stream.
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1. A forwardly directed fluid jet crossing catheter comprising:
a manifold having a substantially straight tubular section and an off-line tubular section, said substantially straight tubular section having a proximal end and a distal end, said off-line tubular section being connected between said proximal and distal ends of said substantially straight tubular section;
a flexible elongated catheter tube in communication with the substantially straight tubular section, the flexible elongated catheter tube having a proximal end and a distal end;
a hollow tapered tip coupled to said distal end of said flexible elongated catheter tube, said hollow tapered tip having a proximal end and a distal end; and
said flexible elongated catheter tube including therein:
a plug seal near the distal end of the flexible elongated catheter tube, at least the plug seal and the hollow tapered tip forming a high pressure infusion cavity within the hollow tapered tip,
an elongated guide wire tube extending from near said proximal end of said substantially straight tubular section, through said plug seal to said distal end of said hollow tapered tip, an opening of the elongated guide wire tube at the hollow tapered tip directed forward of the hollow tapered tip,
an elongated high pressure tube extending from said off-line tubular section through said plug seal and emptying into the high pressure infusion cavity within the hollow tapered tip, and
said elongated guide wire tube having a fluid entry hole in communication with the high pressure infusion cavity, wherein the high pressure tube is configured to deliver high pressure fluid into the high pressure infusion cavity, and from the high pressure infusion cavity to the elongate guide wire tube through the fluid entry hole, the high pressure fluid selectively and forwardly delivered by the opening of the elongated guide wire tube according to a position of a guide wire therein.
2. The forwardly directed fluid jet crossing catheter of
3. The forwardly directed fluid jet crossing catheter of
4. The forwardly directed fluid jet crossing catheter of
5. The forwardly directed fluid jet crossing catheter of
6. The forwardly directed fluid jet crossing catheter of
7. The forwardly directed fluid jet crossing catheter of
8. The forwardly directed fluid jet crossing catheter of
9. The forwardly directed fluid jet crossing catheter of
10. The forwardly directed fluid jet crossing catheter of
11. The forwardly directed fluid jet crossing catheter of
12. The forwardly directed fluid jet crossing catheter of
13. The forwardly directed fluid jet crossing catheter of
14. The forwardly directed fluid jet crossing catheter of
15. The forwardly directed fluid jet crossing catheter of
16. The forwardly directed fluid jet crossing catheter of
17. The forwardly directed fluid jet crossing catheter of
in the tubular flow configuration the guide wire extends from the opening of the flexible guide wire tube and a flow of high pressure fluid from the high pressure infusion cavity generates a tubular jet of fluid having a first velocity from the opening and aligned along the guide wire, and
in the solid flow configuration the guide wire is withdrawn from the opening of the flexible guide wire tube and the flow of high pressure fluid from the high pressure infusion cavity generates a solid jet of fluid having a second velocity from the opening, the second velocity greater than the first velocity.
18. The forwardly directed fluid jet crossing catheter of
19. The forwardly directed fluid jet crossing catheter of
20. The forwardly directed fluid jet crossing catheter of
21. The forwardly directed fluid jet crossing catheter of
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This application claims priority from the earlier filed U.S. Provisional Application No. 60/934,284 filed Jun. 12, 2007, entitled “Front Spray Catheter”, and is hereby incorporated into this application by reference as if fully set forth herein.
1. Field of the Invention
The present invention relates to the field of catheters, and more particularly, relates to a forwardly directed fluid jet crossing catheter used for the purpose of crossing a Chronic Total Occlusion (CTO), whereby a moderate speed and safe velocity fluid jet stream is used to wear away arterial lesions forming a CTO and advance therethrough. Chronic total occlusions are arterial lesions that have progressed to the point where there is no flow through the vessel (total occlusion). Furthermore, it is generally considered highly difficult to cross a CTO with a standard support guidewire. In other words, if a total occlusion is easily crossed with a standard guidewire, it is not a chronic total occlusion. Furthermore, coronary chronic total occlusions have been characterized as having tough fibrous and even calcific caps with a softer interior. This invention is intended to help a guidewire penetrate the chronic total occlusion by directing a moderate speed fluid jet at the occlusion.
The forwardly directed fluid jet crossing catheter is designed to cross chronic total occlusions in a peripheral or coronary artery. Bodies of scientific evidence have indicated that after opening by crossing a coronary chronic total occlusion in a patient, the patient is benefited thereby. Although the presence of a chronic total occlusion usually means there is some collateralization, opening of a chronic total occlusion provides a greater flow reserve. As a result, the opening of chronic total occlusions in a patient has been shown to have improved patient morbidity and mortality. Furthermore, a peripheral procedure can be expedited by crossing peripheral chronic total occlusions. In the case of critical limb ischemia cases, the slow progression of a peripheral artery disease may result in total occlusions in peripheral arteries that are difficult to cross with conventional wires. Other methods, such as the use of a laser, can facilitate this crossing capability for peripheral arteries depending on the amount of calcification.
2. Description of the Prior Art
The crossing of chronic total occlusions is a relatively new treatment modality. As such, the field is not mature with products that are proven in this challenging task, especially for chronic total occlusions in a coronary artery. There are a few products that are being used for this coronary treatment. In general, the first choice of physicians is the use of improved guidewires of which there are many. The Confienza Conquest wire is an example of a very stiff tip wire used to penetrate the fibrous cap of a chronic total occlusion. However, the use of this type of stiff wire for chronic total occlusions is challenging and time consuming resulting in an increased radiation exposure to the patient. Other devices that have been tried include the FrontRunner by Lumend which is a clamshell type device for mechanically opening its blunt jaws at the face of the chronic total occlusion. This device was unsuccessful some of the time so it was not seen as being reliable. Another device is the Safe Cross system from Interluminal Therapeutics. This system consists of a radio frequency ablation wire coupled with an Optical Coherence Detection device to ensure that the wire does not burn through the vessel wall. Although this system is considered generally reliable by trained professionals, it has some limitations. First, the method is slow. Second, if a channel is burned next to the vessel wall, it can be difficult to direct the wire to take an alternative path. Another device is a re-entry device by Lumend (Outback Catheter). This device provides a procedure for crossing a peripheral chronic total occlusion by purposely directing a guidewire into the subintimal space of the vessel. Once the guidewire is beyond the chronic total occlusion, the re-entry catheter directs the guidewire back into the true lumen. Although this is a novel technique, it is not uniformly accepted, nor is this type of procedure comfortable for physicians to perform. Lasers can be used to cross peripheral chronic total occlusions and can facilitate the crossing capability for peripheral arteries depending on the amount of calcification. The present invention uses a moderate speed fluid jet stream to open a passage through, i.e., to cross, a chronic total occlusion. As a result, the treatment will be cool, directable (since the device is torqueable) in the true lumen of the vessel, and rapid. Preferably, the device will find the true lumen since medium velocity fluid jet streams will naturally find a dissection plane (the easiest path) or through one or more microchannels of the chronic total occlusion. These attributes are seen as distinct advantages over competitive treatment options.
The general purpose of the present invention is to provide a forwardly directed fluid jet crossing catheter. The forwardly directed fluid jet crossing catheter uses a single saline fluid jet stream, preferably in tubular flow form and/or in solid flow form, to penetrate and advance through a chronic total occlusion. The concept for the present invention stemmed from vessel safety testing that had been done with thrombectomy catheters. Collective findings of numerous animal studies have shown that the side exhaust flow velocities from thrombectomy catheters were safe although the internal fluid jet streams were so fast that they could possibly damage an artery when it was contacted. Thrombectomy catheters, using cross stream jet technology, have two distinct sets of windows (or orifices). There is one set of inflow windows that is near the origin of the internal high velocity fluid jet streams and another set of side exhaust windows that is located proximally. The concept behind the forwardly directed fluid jet crossing catheter, which can also be referred to as a front spray catheter, is to provide a velocity that is less than the high velocity fluid jets of thrombectomy catheters that will still be safe for contacting the vessel wall, and yet higher than the side exhaust velocity of thrombectomy catheters so that it will be efficacious in penetrating through a tough organized clot.
An important feature of the present invention is the small crossing profile of the fluid jet catheter. Since the device of this invention is used to cross chronic total occlusions, the smaller the crossing profile the better the chance to successfully navigate across the lesion. Therefore, an exhaust lumen as used in cross stream technology becomes a feature that is not used in order to reduce and minimize the crossing profile.
The invention uses a proximal catheter and a connected smaller diameter distal catheter which, for the most part, form a low pressure cavity and a high pressure cavity, respectively, through which a guidewire tube and a high pressure tube generally align. The distal end of the high pressure tube terminates in the high pressure cavity to communicate with and to pressurize the high pressure cavity. An entry hole is included in the distal region of the guidewire tube where such entry hole is located in the high pressure cavity to provide communication between the high pressure cavity and the lumen of the guidewire tube. High pressure fluid emanating from the lumen of the high pressure tube pressurizes the high pressure cavity, whereby the high pressure fluid passes through the entry hole in the guidewire tube and passes into the lumen of the guidewire tube to surround a co-located guidewire. Thence, the high pressure fluid flows distally along the remaining lumen space, as well as along the guidewire, in a cylindrical flow form to emanate from the guidewire lumen as a distally directed fluid jet stream having cylindrical flow form. The guidewire can be retracted a short distance to influence the shape of the cylindrical flow. The forwardly directed fluid jet crossing catheter is essentially a guide catheter with a reduced radius distal end in the form of a distal catheter tube. The distal catheter tube has co-located components which comprise a formable and shapeable catheter tip region. The device can be deployed over a standard guidewire if the physician finds difficulty crossing a lesion. The small diameter of the distal end ensures that a strong cylindrical flow fluid jet stream forms around the guidewire. By torqueing the forwardly directed fluid jet crossing catheter, the optionally bent tip can be directed along and navigate a tortuous anatomy. The velocity of the emanated fluid jet stream can be modified not only by adjusting the pumping speed of a drive unit, but also the velocity and flow rate of the fluid jet stream can be influenced by the amount of engagement of the guidewire within the guidewire tube which is located, in part, within the reduced radius distal catheter tube. For example, if the guidewire is repositioned proximally into the catheter, more of the distal lumen becomes available since there is no guidewire contained therein whereby the jet volume is increased.
According to one or more illustrations of the present invention, there is provided a forwardly directed fluid jet crossing catheter having features and components including a manifold and closely associated components located therein and thereupon, a proximal catheter tube, a smaller distal catheter tube attached to and extending from the proximal catheter tube, an internal adhesive plug seal in the proximal portion of the distal catheter tube separating the lumens of the proximal catheter tube and the distal catheter tube, a low pressure cavity extending proximally from the adhesive plug seal and along the lumen of the proximal catheter tube connecting and communicating with a manifold in a low pressure region, a high pressure cavity extending distally from the adhesive plug seal and along the lumen of the distal catheter tube to and including a tapered tip and tapered tip lumen, a high pressure tube attached to and extending generally from the manifold through the lumen of the proximal catheter tube and co-located low pressure cavity, through the adhesive plug seal and into the lumen of the distal catheter tube and co-located high pressure cavity to openly terminate in the distal region of the high pressure cavity, a guidewire tube attached to and extending generally from the manifold through the lumen of the proximal catheter tube and co-located low pressure cavity, through the adhesive plug seal and into the lumen of the distal catheter tube and co-located high pressure cavity to openly terminate at the distal end of the high pressure cavity, and an entry hole in the distal region of the guidewire tube which is located in the high pressure cavity to provide communication between the high pressure cavity and the lumen of the guidewire tube.
One significant aspect and feature of the forwardly directable fluid jet crossing catheter is a minimal reduced distal cross section in order to enhance the ability to cross chronic total occlusions in small or narrow vascular regions.
Another significant aspect and feature of the present invention is the use of a forwardly directed fluid jet stream in combination with a formable and shapeable catheter tip region.
Still another significant aspect and feature of the present invention is a formable and shapeable catheter tip region having a section of annealed high pressure tube within a distal catheter tube and a flexible tapered tip providing a directable and shapeable atraumatic tip where such formable and shapeable catheter tip region can positively influence tracking along the vasculature.
Still another significant aspect and feature of the present invention is a forwardly directed fluid jet crossing catheter with a flexible tapered tip that gradually transitions substantially to the diameter of a guidewire to aid in tracking and in crossing a chronic total occlusion.
Yet another significant aspect and feature of the present invention is the positioning of a guidewire within a guidewire lumen to influence the velocity and/or flow rate and the structure of a fluid jet stream.
Still another significant aspect and feature of the present invention is a forwardly directed jet stream delivered in a cylindrical flow fashion about a guidewire.
Still another significant aspect and feature of the present invention is a forwardly directed fluid jet crossing catheter having a dedicated guidewire lumen along the entire length of the catheter so that guidewires can be exchanged.
Yet another significant aspect and feature of the present invention is the use of a proximal catheter tube generally forming a low pressure cavity.
Yet another significant aspect and feature of the present invention is the use of a distal catheter tube generally forming a high pressure cavity.
Yet another significant aspect and feature of the present invention is the use of an adhesive plug injected through a hole in the distal catheter tube to substantially and separatingly seal the lumens of the distal catheter tube and the proximal catheter tube in order to substantially provide a high pressure cavity and a low pressure cavity.
Yet another significant aspect and feature of the present invention is a forwardly directed fluid jet crossing catheter that isolates a high pressure cavity from the manifold of the catheter by the use of an interceding low pressure cavity.
Still another significant aspect and feature of the present invention is the use of a high pressure tube connected to and extending from a manifold and through the co-located proximal catheter tube and low pressure cavity, through an adhesive plug seal and thence into and openly terminating in the high pressure cavity.
Still another significant aspect and feature of the present invention is the use of a guidewire tube connected to and extending from a manifold and through the co-located proximal catheter tube and low pressure cavity, through an adhesive plug seal and thence into and terminating beyond the high pressure cavity.
Still another significant aspect and feature of the present invention is the use of an entry hole in the distal region of the guidewire tube which communicates with the high pressure cavity of the distal catheter tube to provide for entry of high pressure fluid into the guidewire tube.
Still another significant aspect and feature of the present invention is the use of a high pressure cavity for transfer of high pressure fluid from the lumen of a high pressure tube through the entry hole of the guidewire tube to provide a cylindrical flow of a high pressure fluid distally along the portion of the guidewire lumen not occupied by a co-located guidewire, as well as a cylindrical flow along the co-located guidewire.
Yet another significant aspect and feature of the present invention is an internal high pressure tube sealed inside one or more guide catheter tubes for the purpose of delivering pressurized saline to a formable and shapeable catheter tip region.
Yet another significant aspect and feature of the present invention is the use of a portion of a guidewire tube to deliver high pressure fluid to a chronic total occlusion.
Having thus briefly described embodiments of the present invention and having mentioned some significant aspects and features of the present invention, it is the principal object of the present invention to provide a forwardly directed fluid jet crossing catheter.
Other objects of the present invention and many of the attendant advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, in which like reference numerals designate like parts throughout the figures thereof and wherein:
The proximal ends of a guidewire tube 42 having a lumen 44 (
A ferrule 86 is aligned and secured within a passageway 88 of the threaded high pressure connector 18, the combination of which is partially aligned within a passageway 90 of the Luer fitting 20. The proximal end of the proximal high pressure tube 46, which is utilized for delivery of high pressure ablation liquids, is suitably secured in an internal passageway of the ferrule 86 to communicate with the interior passageway 88 of the threaded high pressure connector 18, as shown in
The guidewire tube 42 and the high pressure tube 46 are shown extending along several areas or locations:
(1) portions of the guidewire tube 42 and the high pressure tube 46 are both shown at the distal end of the low pressure cavity 30 and are both aligned (a) within the distal portion of lumen 50 of the proximal catheter tube 28, and (b) are both aligned in the proximal portion of lumen 52 of the distal catheter tube 32, proximal to the adhesive plug seal 54;
(2) a portion of the guidewire tube 42 and the high pressure tube 46 are both shown encapsulated and affixed directly within the distal catheter tube 32 by the adhesive plug seal 54 which is preferably injected, in a fluid state, through an injection hole 112 in the distal catheter tube 32 and which is subsequently hardened or cured;
(3) the high pressure tube 46 is shown in the high pressure cavity 34 (a) aligned distal to the adhesive plug seal 54 and extending distally along a greater portion of the lumen 52 of the distal catheter tube 32, and (b) openly terminating a short distance proximal to the tapered tip 36; and,
(4) a portion of the guidewire tube 42 is shown in the high pressure cavity 34 (a) aligned distal to the adhesive plug seal 54 and extending distally along the lumen 52 of the distal catheter tube 32, and (b) extending beyond the end of the high pressure tube 46 into and securing within the lumen 37 of the tapered tip 36 by the compression of the marker band 40 about the distal end of the tapered tip 36.
An entry hole 114, which is preferably elongated, extends through the wall of the guidewire tube 42 to provide communication between the lumen 44 of the guidewire tube 42 and the region outside of the guidewire tube 42, and more specifically, to provide communication between the lumen 44 of the guidewire tube 42 with the high pressure cavity 34 with which the lumen 48 of the high pressure tube 46 also communicates. Communication also occurs between the lumen 48 of the high pressure tube 46 and the lumen 44 of the guidewire tube 42 through the common high pressure cavity 34, whereby a high pressure fluid is distally emanated as a high pressure fluid jet through the extreme distal end of the guidewire tube 42. Consideration is also given to the torqueability and flexibility of the proximal catheter tube 28 and the distal catheter tube 32 by the use of braided Pebax® tubing for each. Consideration is given to flexibility by the use of a polyimide for construction of the guidewire tube 42. Consideration is also given for shapeability and directability as provided by a formable and shapeable catheter tip region 49 (
This invention describes a catheter used for purposes of crossing chronic total occlusions. The forwardly directed fluid jet crossing catheter 10 is compatible with and can be driven by the AngioJet® console (often referred to as the AngioJet® Ultra System) described in patent application Ser. No. 11/237,558 filed Sep. 28, 2005, entitled “Thrombectomy Catheter Deployment System”, which is pending. The forwardly directed fluid jet crossing catheter 10 can also be incorporated into use with various support components known in the art. AngioJet® thrombectomy catheters use high velocity jets to generate strong secondary flows to liberate, macerate and remove thrombus. The system includes a roller pump to ensure that the waste flow is equivalent to the volumetric flow rate of saline pumped into the patient via the high velocity jets known as isovolumetric flow. In the case of the forwardly directed fluid jet crossing catheter 10, a single mid-range velocity fluid stream jet can be directed forward to seek a path through the chronic total occlusion 126. The forwardly directed fluid jet crossing catheter 10 may not necessarily have a waste flow that comes out of the patient, so it is not necessarily an isovolumetric catheter.
The typical mode of operation for crossing a coronary CTO is a planned procedure which is typically not an emergency situation. In general, a patient with a known chronic total occlusion means that there was a previously failed attempt to cross a total occlusion with a guidewire where, as a result, a separate intervention may be planned at a later date to cross the chronic total occlusion in order to provide the patient with a greater flow reserve. Peripheral procedures may involve extreme difficulty in positioning a guidewire at a distal location. It may be common for the interventionalist to have a set of tools available to assist in crossing these difficult-to-cross occlusions. Some physicians may commonly rely on a laser as an adjunct tool, while others may have a set of guidewires used for negotiating the occlusions. In either case, the mode of operation would be similar. The physician would determine that a particular occlusion needed an adjunct tool to help crossing; in this case, the forwardly directed fluid jet crossing catheter 10, the operation of which can be supported by the AngioJet® console or in the alternative, can be supported by combinations of other peripheral components. The forwardly directed fluid jet crossing catheter 10 can be combined with a pump in a sterile package using a sterile technique. The sterile pump would be loaded into the AngioJet® console and a supply of heparinized saline would be connected to the pump via a common bag spike and primed by stepping on a foot switch. The forwardly directed fluid jet crossing catheter 10 would be advanced to the treatment site by riding over the guidewire 120. The flexible tip 36 of the forwardly directed fluid jet crossing catheter 10 would be directed at the occlusion and the foot pedal depressed, thus providing a fluid jet stream of saline that would find the natural dissection plane and/or microchannels through the chronic total occlusion, whereby the guidewire 120 would be advanced. Then, the forwardly directed fluid jet crossing catheter 10 would be advanced and the process repeated until the occlusion was crossed. Once the occlusion was crossed, the intervention to treat the occlusion with either atherectomy or stenting could proceed. If the physician decided to use another guidewire, the physician could exchange the guidewire being used without loosing position and then introduce a new guidewire.
Various modifications can be made to the present invention without departing from the apparent scope thereof.
Bonnette, Michael J., Morris, David B., Thor, Eric J.
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